Author: matheinboulomenos

This is a continuation of the ongoing series on representation theory, see Overview of blog posts for previous posts on that subject.

Let be a group and let be a field. We begin with some remarks on dual spaces and tensor products of representations.

Lemma/Definition 5.1 If is a -module, then the dual space is a -module via . This is called the dual representation.

Proof This can be checked via an explicit (but boring) computation, so let’s do a more conceptual proof (feel free to ignore it if you’re not into categories): The representation can be considered a functor , where we regard as a one-object category. The inversion map is an anti-isomorphism, i.e. an isomorphism , as , which means that inversion gives a functor , now if we compose the functors , we get a covariant functor , since we composed two contravariant and one covariant functors, this is the dual representation defined in the lemma.

Lemma/Definition 5.2 If and are two -modules, then is a -module via the “diagonal action” given on elementary tensors by .

Proof As before, this is a straightforward computation. For a more conceptual proof, one can use that the diagonal map induces a ring homomorphism given on basis elements by (this is called “comultiplication” in the setting of Hopf algebras) and that is canonically a -module (where the first copy of acts on and the other one on ), so one can restrict scalars along the comultiplication .

Lemma/Definition 5.3 If and are two -modules, then is a -module where is defined via

Proof this is a straightforward computation. One can also give a conceptual proof similar to those before using the maps from the two previous proofs.

Lemma 5.4 Let and be -modules, then we have .

Proof clear from the definition of the -module structure on .

Lemma 5.5 Let and be two finite-dimensional -modules, then the map given on elementary tensors by is an isomorphism of -modules.

Proof That this is an isomorphism of -vector spaces is known from linear algebra. One checks that it is -equivariant.

For the rest of this post, let be a finite group and let be a field of characteristic . (All representations shall have coefficients in )

By Maschke’s theorem, every representation of with coefficients in can be decomposed as a direct sum of irreducible representations. If is an irreducible representation and is a finite-dimensional representation, then we get by Schur’s lemma that the number of times that appears in the decomposition of is equal to (cf. 3.19)
Let us revisit the averaging method from proof of Maschke’s theorem to find another expression for this dimension.

Lemma 5.6 Let be a -module, then the map , is a linear projection.

Proof To see that is well-defined note that for , we get , since the map is a bijection. That restricts to the identity on and linearity is clear.

Lemma 5.7 Let and be finite-dimensional, then

Proof Since the map , is a projection onto the subspace (by 5.6), we get that . Using the isomorphism (by 5.5), we get that . Using properties of traces and the definition of the dual representation, this equals .

Let us ponder for a moment what we have shown so far. We know that every finite-dimensional representation of may be decomposed as a direct sum of irreducible submodules. For each irreducible representation of , we can compute the multiplicity of in the decomposition of if we know and (cf. the discussion preceeding 5.6). But now 5.7 gives us an expression for these dimension that only involves the traces and . It thus makes sense to give a special name to the function

Definition 5.8 Let be a finite-dimensional representation of , then the function is called the character of and is denoted by . (Note that the trace of a matrix is invariant under conjugation, so the character doesn’t depend on a choice of basis for .)

Using the above discussion, we obtain the following surprising corollary:

Corollary 5.9 A finite-dimensional representation of is uniquely determined by its character: if two finite-dimensional representations of have the same character then they are isomorphic.

This concludes a short intro and motivation for character theory, we will continue the study in future posts.

This entry is a direct continuation of this post and is part of a larger series on representation theory that starts with that post. In this blog post, we continue our study of semisimple rings and bring it to a conclusion by proving a classification. Then we apply this insight into the structure of semisimple algebras to the the group algebra to get more information on irreducible representations.

Endomorphism Rings of Semisimple Modules

The goal behind the following lemmas and corollaries is to compute the endomorphism ring of a semisimple module that is a finite direct sum of simple modules, the motivation being that to finite-dimensional representations in the semisimple case (cf. 3.20) and to a semisimple rings as a module over itself (cf. 3.24).
The idea behind the proof is simply to “multiply out” the hom set that gives us endomorphisms by pulling out (finite) direct sums from both arguments and then use Schur’s lemma to understand the hom sets between simple modules.

Definition 4.1 For a ring and a natural number , denotes the matrix ring with entries in with the usual formulas for addition and multiplication.

The following lemma is a generalization of a well-known fact from linear algebra:

Lemma 4.2 Let be a right module over a ring , then

Proof Lets index the direct summands in (so for all , but we’re keeping track of which component it is)
Note that as abelian groups, the isomorphism is clear, since we have
Now for each summand at least as an abelian group, which we can use to idenitfy elements in with elements in by sending the component living in with the entry at the position . The verification that this respects multiplication amounts to the same calculation that shows that composition of linear maps corresponds to matrix multiplication.

This gives a description of the endomorphism rings of finite direct sums of simple modules, where each simple submodule is in the same isomorphism class. To properly “multiply out” our endomorphism rings, we just need another application of Schur’s lemma:

Lemma 4.3 Let and be modules over a ring and suppose that , then we have as rings
If is a -algebra for some field , then this an isomorphism of -algebras.

Proof We always have an injection given by . Here means that we apply on the first, and on the second summand. Since addition and composition of such endomorphisms can be carried out component-wise, this is a ring homomorphism and if everything is a -vector space, it is also -linear. The image of that map is the set of endomorphisms of that map and to itself. Given our conditions, if we have any endomorphism of , restricting to and composing with the projection , gives a homomorphism which is zero by assumption. This shows that the endomorphism maps to itself, and by the same argument , thus the map is surjective.

Corollary 4.4 Let be a right module over a ring that is a finite sum of simple submodules such that the are pairwise non-isomorphic. Let be the endomorphism rings, then

Proof By Schur’s lemma, there are no nonzero homomorphisms between semisimple modules that don’t have a simple submodule in common, so that we can apply 4.3 times to get that . Now apply 4.2 to each factor.

Using this, we get a partial converse to Schur’s lemma:

Corollary 4.5 Let be a module that is a finite sum of simple submodules, then is simple if and only if the endomorphism ring of is a division ring.

Proof One direction is just Schur’s lemma. The other direction follows from 4.4 by noting that the only way that is a division ring is if .

Enter the Matrix Ring

Corollary 4.4 already gives us a description of endomorphism rings of modules which are finite sums of simple submodules. In the description, matrix rings over division algebras appear. This means to deepen our understanding of those endomorphism rings, we should study matrix rings.

We begin by studying their ideals:

Lemma 4.6 Let be a ring and , then the map from two-sided ideals of to two-sided ideals of , sending to is a bijection. (Here is the subset of all elements in where each entry is contained in )

Proof It’s clear that is a two-sided ideal in when is a two-sided ideal in . It’s also clear that the map is injective (we can recover from just by looking at the set of elements of that appear in the entries of the matrices in .
For surjectivity, let be the matrix that is zero everwhere except at , where it is . Then if is a twosided ideal and , we compute that is the matrix that agrees with at the place and is zero everywhere else. A calculation shows that the set of elements in that appear as an entry in the place is a two-sided ideal in , but then , because we can permute the entries of a matrix that has only one non-zero entry by multiplying from the left and right by permutation matrices (and then by taking sums, we get that every element in is contained in .
On the other hand , because we can first multiply a matix from the left and right by permutating matrices and then multiply by from the left and right to get that we could have also defined as the set of elements which appear as any matrix entry for elements in . Thus .

This lemma implies in particular that if is a division ring, then has no proper non-zero two-sided ideals. We can use this to together with another property that holds in general for finite-dimensional modules:

Lemma 4.7 Let be a module over a ring and suppose that contains a division ring such that is a finite-dimensional -vector space. (We don’t require that is a -algebra, i.e. that is commutative and in the center of ), then contains a simple submodule.

Proof Start with any non-zero submodule of . e.g. itself. If is not simple, choose a proper non-zero submodule of , then if that submodule is not simple choose a proper non-zero submodule etc.
Since the dimension over has to decrease at every step, this process has to terminate, which gives us a simple submodule.

Lemma 4.8 Let be a ring that has no proper nonzero two-sided ideals that has a minimal right ideal , then is semisimple and every simple module over is isomorphic to

Proof Let be such a ring and let be a minimal right ideal, then we can make a two-sided ideal out of by taking the product .
Since doesn’t contain proer nonzero two-sided ideals and , we get that . For each fixed , is a homomorphic image of the simple module under the image of the right -linear map , so the image is either isomorphic to (and hence simple) or zero by Schur’s lemma.
The implication (2.) implies (3.) (compare the proof or the remark after the proof) in 3.14 gives us that there is a subset such that . Thus is semisimple. 3.25 implies that every simple module is isomorphic to a direct summand in the sum , but every summand of that is isomorphic to which implies that every simple module is isomorphic to .

A natural question is how to recover from . The following lemma provides this, if we also have the module :

Lemma4.9 Let be a ring and consider as the column space, which is a right -module, then we get that . If we think of as a submodule of , then is given by all scalar multiples of the identity.

Let be the matrix that has zeroes everywhere except a at , let be the vector in that has zeroes everyhwere except a one in the -th component. For any let be the permutation matrix associated to such that applying that matrix corresponds to permuting the entries with .
Then for any , we get that . Now multiplying with corresponds to making all entries zero except the first entry which is left untouched. Thus is a multiple of , so we can find a unique such that .
For every let be the transposition that switches and , then we have .
Since the form a basis, we have seen that is just scalar multiplication (from the left) with , or as a matrix , where denotes the identity matrix.
This proves .

Putting the last few lemmas together, we obtain the main result on modules over matrix rings over a division algebra:

Lemma 4.10 Let be a division algebra and , then is semismple and the unique simple right module over is and . (Here we’re regarding as row vectors so that the right -action makes sense.)

Proof 4.6 implies that has no nonzero proper two-sided ideals and 4.7 implies that it has a simple submodule, so that 4.8 applies and is semisimple with only one isomorphism class of simple modules.
The statement that is a simple -module is just linear algebra:
Given any non-zero vector in , for all , there’s a linear transformations (i.e. a matrix) that sends to . Thus is a simple module over as every non-zero submodule is the whole module. The part about the endomorphism ring follows from 4.9.

Now we come to the main theorem about semisimple rings that classifies them and also relates their ring-theoretic properties to their modules.

Theorem 4.11 (Artin-Wedderburn) A ring is a semisimple iff there exist natural numbers and division rings such that .
Here the is the number of simple modules up to isomorphism, is the endomorphism ring of and . In particular, is uniquely determined and the and are unique up to isomorphism and permutation of the factors.

Proof Note that for every ring , considered as a right module over itself, we have an isomorphism of rings by applying 4.9 with . Let by a decomposition of into simple right submodules such that the are pairwise non-isomorphic. Let .
By 4.4, we have an isomorphism . Here is uniquely determined as number of simple modules over up to isomorphism. The together with the are uniquely determined as the endomorphism rings of the simple modules and the dimension of the simple modules over their endomorphism ring (cf. lemma 4.10 for modules over matrix rings over a division algebra and 2.5 for modules over a product).
For the reverse direction, note that matrix rings over division rings are semisimple by 4.10 and 3.15 implies that finite products of semisimple rings are semisimple.

After having finally proved the main theorem for semisimple rings, we can give lots of applications:

Corollary 4.12 Semisimplicity for rings is left-right symmetric, i.e. if is symmetric, so it is opposite ring .

Proof Using 4.11, it’s enough to show that since the opposite ring of a division ring will be a division rings as well.
An isomorphism is given by transposition .

Corollary 4.13 Let be a semisimple ring, then the following are equivalent:

is commutative

For all simple -modules , the endomorphism ring is a field and .

Proof We apply 4.11: is commutative iff all are and all are commutative, i.e. fields.

Corollary 4.14 Let be an abelian group, then every irreducible real representation of is at most 2-dimensional.

Proof Let be an abelian finite group. Since is the algebraic closure of and has dimension 2 over , we get that all finite field extensions of have dimension at most 2. By 4.13 all simple -modules are one-dimensional over their endomorphism rings, which are finite field extensions of by 3.27 and 4.13, so the endomorphism rings are at most two-dimensional, thus all simple -modules have dimension at most 2 over .

Corollary 4.15 Let be a finite group and be an algebraically closed field such that the characteristic of doesn’t divide the order of , then the following are equivalent:

is abelian

All irreducible representations of are one-dimensional

The number of irreducible representations is equal to the order of

Proof The equivalence of (1) and (2) follows from 4.13 and 3.27 and 3.29, since 3.27 and 3.29 together imply that the endomorphism ring of any simple -module is , so the statement follows from 4.13.
The equivalence of (2) and (3) follows from 3.30

Reminder For a group , the abelianization is the largest commutative quotient of . Explicitly, it is given by the quotient of the subgroup generated by all commutators. It has the universal property that every morphism from to an abelian group factors uniquely through the map .

Corollary 4.16 Let be a finite group and be an algebraically closed field such that the characteristic of doesn’t divide the order of , then the number of one-dimensional representations of up to isomorphism is equal to the order of the abelianization

Proof One-dimensional representations are homomorphisms .
Since is commutative, these correspond to homomorphisms , i.e. one-dimensional representations of . One-dimensional representations are automatically irreducible and 4.15 tells us that since is abelian, there are exactly up to isomorphism.

The Center of the Group Algebra

The last corollary gives a partially answers the question for the number of irreducible representations of a group, by characterizing the number of one-dimensional representations in terms of the group theory of . In this section, we give a group-theoretic characterization of the number of all irreducible representations. (Given suitable assumptions on the field)

Definition4.17 If is a ring, then the center is defined as . It is a commutative subring of .

Lemma 4.18 If is a ring and , then consits of those diagonal matrices where all diagonal entries are the same value that lies in . So we have an isomorphism of rings .

Proof We rergard as row vectors which is naturally a right -module. Then for , the map is -linear, because for , we have .
By 4.9 is a diagonal matrix where all diagonal entries are the same. Clearly the diagonal entry must lie in , as commutes with other such diagonal matrices.

Lemma 4.19 If and are rings, then .

Proof This is an easy computation. Multiplication in is defined component-wise.

Corollary 4.20 If is a semisimple ring with the Artin-Wedderburn decomposition , then .

Corollary 4.21 If is a semisimple algebra over a field , then where is the number of simple -modules up to isomorphism. We have equality if is algebraically closed.

Proof By 4.11, the number of simple -modules up to isomorphism is if . By 4.20, we have . Each factor has least dimension , which shows the inequality.
If is algebraically closed, then for all by 3.29 which shows that equality holds.

Corollary 4.22 If is semisimple real algebra and is the number of simple -modules up to isomorphism, then

Proof Argue as in the proof of 2.21 and use the fact that where is a finite-dimensional division algebra over has to be isomorphic to or , since it is a finite field extension of , so the dimension is at most two.

These corollaries relate the number of simple modules of a semisimple algebra and their center. Thus the next thing to do is to study the center of group algebras.

Reminder If is a group, then for , the conjugacy class of consists of all elements in that are conjugate to . In other words, if we consider the action , then this is the orbit of under this action. The different conjugacy classes are the minimal subsets of that are closed under conjugation and form a partition of .

Lemma 4.23 Let be a field and let be a group (we don’t need it to be finite). Then has a -basis given by the set of elements of the form where varies over all conjugacy classes of with finitely many elements.

Proof Since is a -algebra with a -basis given by , we can check if an elements is in the center just by checking if it commutes with every element of . Let be an element of (so all but finitely many are zero. Then is in the center of if and only if for all , we have .
Writing out , this equation becomes . Here we used that is a bijection.
Comparing coefficients, this is equivalent to for all .
If this holds for all , then we get that the (finite) set of elements such that is closed under conjugation and if two elements inside are conjugate, their coefficients are equal. Take a system of representatives for where acts on by conjugation. Then by the above considerations, we get that , where is the conjugacy class of . This shows that the set of elements of the form where is a finite conjugacy class is a generating system for . It is linearly independent because distinct conjugacy classes are distinct.

Theorem 4.24 If is a finite group and is a field such that the characteristic of doesn’t divide the order of and let be the number of irreduible representations, up to isomorphism. Let be the number of conjugacy classes of . Then with equality if is algebraically closed. If , then we have .

Proof By 4.23 is the dimension of the center of . Now apply 4.21 and 4.22.

Thus we have obtained a relation between the number of irreducible representations and the element structure of by heavily employing the structure theory for semisimple rings. This is a nice illustration of the power of ring-theoretic tools in representation theory.

This post is the third one in a series on representation theory. The previous posts are this one and that one (in this order.) The nature of this post is mostly ring-theoretic, but we will give applications to representation theory throughout the development of the general theory.

Semisimple Modules

Under suitable assumption on and , Maschke’s theorem (1.22) tells us that any submodule of a -module is a direct summand, i.e. we can find a complement.
One can try to apply this repeatedly to decompose a -module into smaller submodules. If the dimension is finite, then at some point we have to end up with a direct sum of modules that don’t have a non-zero proper submodule. This is because if one direct summand had a non-zero proper submodule, we could just decompose it further by Maschke’s theorem. The assumption of finite dimension implies that this process has to terminate, as the dimension of the summands decreases every time we decompose something.
This motivates the following definition to give a name to the modules we obtained as summands in the end:

Definition 3.1 A non-zero module over a ring is called simple if it doesn’t have a proper non-zero submodule.

Example 3.2 If is a field, or more generally a division ring, then a vector space over is simple iff it is one-dimensional.

Example 3.3 If we consider modules over , i.e. abelian groups, then simple modules are just simple abelian groups. It’s known that simple abelian groups are the groups that are cyclic of prime order: .

Example 3.4 If is a field, and we consider -modules, i.e. -vector spaces equipped with a choice of endomorphism (cf. the first section of the last entry), then a module is simple iff it doesn’t have a non-zero proper -invariant subspace. One can show that this equivalent to being isomorphic to for some irreducible . In particular, if is algebraically closed, then simple -modules are precisely the one-dimensional ones. (Where the endomorphism necessarily acts by scalar multiplication.) This means that over an algebraically closed field, an endomorphism of a finite-dimensional vector space is diagonalizable, if and only if the associated -module is a direct sum of simple modules. (And in general, the associated -module is a direct sum of simple modules if and only if the the endomorphism is diagonalizable over an algebraic closure.) We will encounter the condition of being a direct sum of simple modules later in this post.

Generalizing the last two examples, we have the following result:

Lemma 3.5 If is any ring and is a maximal left ideal, then is a simple module. Conversely, every simple module is of that form

Proof If is a maximal left ideal, then submodules of correspond to submodules of containing , so is simple by definition of being maximal.
Conversely, if is a simple module and is nonzero, then is a non-zero submodule of , so . This means the map is surjective so we get an isomorphism for some proper ideal . If is not maximal, then there’s a proper submodule containing , which corresponds to a proper non-zero submodule of , which is impossible.

Example/Definition 3.6 If is a field and is a group, then similar to example 3.4, simple -modules are representations with no non-zero proper -invariant subspace. These are called irreducible representations.

Example 3.7 The representations of a cyclic group of order , corresponding to irreducible factors of that we have constructed in 2.6. are irreducible. The reason is that they’re irreducible -modules, where the action of corresponds to the action of a generator of the group. (cf. 3.4 and the proof of 2.6)

We have seen in 3.5 that simple modules are generated by one element, let’s give this property a label (generalizing the notion of cyclic groups):

Definition 3.8 Modules that are generated by a single element are called cyclic modules.

By our considerations in the beginning of the section, we see that when Maschke’s theorem applies and we have a finite-dimensional representation, it decomposes as a direct sum of irreducible subrepresentations. The purpose of the following lemmas is to generalize this. (Because we work without any finiteness conditions, we will need some form of the axiom of choice. If one is only interested in modules that satisfy some finiteness condition (e.g. finite-dimensional modules for an algebra over a field), then the dependence on choice can be eliminated and the arguments are much easier.)

Definition 3.9 A module over a ring is called semisimple if every submodule has a complement, i.e. there exists a submodule such that

Lemma 3.10 Submodules and quotients of a semisimple modules are semisimple.

Proof If is semisimple and is a quotient, then for submodule , we can take the preimage under the projection to get a submodule that projects onto . Then the image under the projection of a complement of will be a complement for . If is a submodule, then we can find a complement , but then so that is quotient of , so the previous case applies.

We will need the following result for an important property of semisimple modules. Most readers will probably be familiar with this, at least in the commutative case:

Lemma 3.11 Let be a ring. Then every proper left ideal is contained in a maximal left ideal.

Proof Let be a proper left ideal and let be the set of all proper left ideals containing . If we have an ascending chain , where , then is an upper bound. This is a proper ideal, because if it wasn’t, some would contain , which is impossible. So Zorn’s lemma applies and we get a maximal element in

Proof Let be a semisimple module over a ring . As by 3.9, submodules of semisimple modules are semisimple, it suffices to treat the case where is cyclic. In that case, contains a maximal submodule by 3.12.
As is semisimple, we can find a submodule such that .
If is not simple, then there is a non-zero proper submodule , but then , which contradicts the maximality of .

We now come to the main result on semisimple modules, the proof is a little technical.
The most important part of the statement for us is the implication (1)=>(2) (cf. 3.16), but we give the full result for completeness.

Proposition 3.14 For a module , the following statements are equivalent:

is semisimple

is a sum of simple submodules

is a direct sum of simple submodules

Proof
(1.) implies (2.): Let be semisimple and let be the sum of all simple submodules, then as is semisimple, we get that for some .
If is non-zero, we get that contains a simple submodule by 3.10 and 3.13, but this contradicts the definition of and the fact that .

(2.) implies (3.): Suppose where all are simple.
Consider the set of subsets such that . This is partially ordered by inclusion and the usual Zorn’s lemma argument works (just take unions of chains as upper bounds) so that we get a maximal element . Suppose that , then for some , we get that , which implies that , since is simple and that intersection is a proper submodule. But then we get which contradicts the maximality of .

(3.) implies (1.): Let with all simple. Let be a submodule. We may assume that is a proper submodule.
Consider the set of subsets such that . This is non-empty, as is a proper submodule, it doesn’t contain some , but then , as is simple.
Now we apply (surprisingly!) Zorn’s lemma to this set, partially ordered by inclusion by taking unions as upper bounds for chains. Let be a maximal element.
Then consider . If this is a proper submodule of , then it must have zero intersection with some for . It follows that , and for all , thus , so that by maximality of , we get , so we can choose non-zero in that intersection. Write for some and
Then is contained in which is zero by the choice of .
Thus is a non-zero element of which is impossible, thus .

Note that the proof for the implication from (2) to (3) actually shows that if a module is a sum of simple submodules, one can find a subset of the index set such that the sum is direct and still gives the whole module.

Corollary 3.15 Direct sums of semisimple modules are semisimple.

Proof Use the equivalence between (1) and (3) in 3.14

Corollary 3.16 If is a finite group and is a field such that the characteristic of doesn’t divide the order of , then any representation of over is a direct sum of irreducible subrepresentations.

Proof Follows from 1.22 and 3.14

We have already seen an instance of this phenomenon in our study of cyclic groups in the semisimple case. (cf. 2.6 and 3.7)

After this not-quite-simple proposition about semisimple modules, we return to simple properties of simple modules.

Let’s first record an observation, so that the statements we’re about to prove make sense:

Lemma 3.17 Let be any ring and let and be modules over , then and are rings and if is a -algebra, they are also -algebras. is a left module over and a right module over and these actions are compatible, i.e. is a -bimodule.

Proof The statement might look complicated, but all we’re doing here is just composing maps: is a ring (or -algebra) under composition of maps and the module structures on are given by composing with endomorphisms from the left or the right. All properties we need follow from properties of composing linear maps

Lemma 3.18 (Schur) Let and be modules over a ring and let be a linear map, then:

If is simple, then is either zero or injective.

If is simple, then is either zero or surjective.

If both and are simple, then is either zero or an isomorphism.

If is simple, then is a division ring. (cf. 3.17)

Proof(1): As is simple, is either or .
(2): As is simple, is either or .
(3): Follows from (1) and (2).
(4): Follows from (3).

Despite the easy proof, Schur’s lemma is quite useful and will be a constant companion while dealing with simple modules. We give a first application.

Lemma 3.19 Let be a semisimple module that is a finite direct sum of simple submodules, write where the are pairwise non-isomorphic. Then for every , set . Then we have an equality . In particular, the exponent is independent of the decomposition, so the decomposition is unique up isomorphism and permutation of the factors.

Proof
Note that this isomorphism is -linear, because the action of is given by composition in the first argument.
Schur’s lemma implies unless , so we get . The case with switched arguments works the in the same way.

Corollary 3.20 Let be a finite group and let be a field such that the characteristic of does not divide the order of , then every finite-dimensional representation can be written as a direct sum of irreducible subrepresentations which are uniquely determined up to isomorphism, including their multiplicity.

Proof Existence follows from 3.16 and uniqueness from 3.19

The last corollary justifies why one pays a lot of attention to irreducible representations, especially when Maschke’s theorem applies.

Semisimple Rings and Algebras

So far, we have just studied (semi)simple modules. A general philosophy in ring theory is to study relations between the internal structure of a ring and the structure of its modules. Whenever there’s a notion for modules, one possible definition for a ring-theoretic property is obtained by just considering a ring as a left, right or two-sided module over itself. (For technical reasons, we will work with right ideals and modules in this section. It will allow us to skip some passage from a ring to its opposite ring in a future post. One can dualize all statements by using that left -modules are right -modules, where is the opposite ring which has reversed order of multiplication. Note that the group algebra is isomorphic to its own opposite ring, via the map given on the basis by .)

If we apply this to the properties we’ve been studying, we get that a ring that is simple as a right module over itself is just a division ring. The way to see this is that every non-zero element must generate the whole ring as a right deal (and by group theory it’s enough to have all right inverses.). We already have a name for that, so that’s nothing new. This doesn’t happen with the following definition:

Definition 3.21 A ring is called semisimple if it is semisimple as a right module over itself.

We’re deliberately not being careful with the chirality here: Theoretically, one should define left and right semisimple, but as we shall see that they are equivalent.

We can apply the theory we have developed for semisimple modules to show how this property is reflected in the structure of the modules over a ring:

Lemma 3.22 A ring is semisimple if and only if all right modules over are semisimple.

Proof One direction is obvious. For the other one, note that if is semisimple, 3.15 implies that all direct sums of , i.e. all free modules are semisimple. By 3.10, this also shows that all quotients of free modules are semisimple. But every module is a quotient of a free module.

Remarkably, this tells us that it would have been sufficient to prove Maschke’s theorem for just for one single representation, the one corresponding to the -module to get decompositions into irreducible representations. (Even infinite-dimensional ones.)

Lemma 3.23 If a ring is a direct sum of non-zero right ideals, then the sum is finite.

Proof Suppose , then we have where all but finitely many are zero. Let be the subset of consisting of the indices such that . Then for any , we have because the sum is direct, this expression is the unique way to write as a sum from elements in where ranges over . since we assumed that all are non-zero, this implies , so that is finite.

Corollary 3.24 A semisimple ring is a finite direct sum of simple right -modules (also called minimal right ideals in this case.)

Proof Apply 3.14 and then 3.23.

Corollary 3.25 Let be a semisimple ring, then every simple right -modules occurs as a direct summand of (as a right -module over itself) and the multiplicity is equal to the dimension of over its endomorphism ring (which is a division ring). In particular, that dimension is finite.

Proof Note that 3.24 implies that 3.19 is applicable to (by which we always mean as a right module over itself in this proof).
Let be the multiplicity with which occurs in the decomposition of as a direct sum of simple submodules. By 3.19 is independent of the decomposition, but it might be zero. But 3.19 tells us that which also tells us two things:
1) The RHS is finite
2) The LHS is non-zero, as .

We want to apply this to the case where is an algebra over a field , but for this it would be nice to know that the are finite-dimensional over . We need some easy results on finiteness conditions.

Lemma 3.26 Let be a field and let and be modules over a finite-dimensional algebra , then if and are finitely-generated over , they are finite-dimensional over and so is .

Proof being finitely-generated means that we can find a -linear surjection . As is a -algebra, this surjection is also -linear. is finite-dimensional over , because is, this implies that is finite-dimensional over . If is finitely generated, let be a finite-generating system, then the map is -linear. It is also injective, because any map from is determined by where it sends the generating system . is a finite-dimensional vector space by the previous part, thus is finite-dimensional.

Corollary 3.27 Let is a finite-dimensional algebra over a field , then all simple modules and their endomorphism rings are finite-dimensional over .

Lemma 3.28 Let be a semisimple algebra over a field and let be a list of all simple modules, up to isomorphism. Let be their endomorphism rings. Then (where all dimensions are finite.)

Proof 3.25 implies that where , this implies that . (3.27 tells us that we don’t have to worry about infinite dimension.)
So the only thing left to show is that . But this is clear: We have , so we just compare the -dimension of both sides.

The following lemma tells us that we can leave out the factors if if is algebraically closed.

Lemma 3.29 If is an algebraically closed field, then every finite-dimensional division algebra over is one-dimensional, i.e. itself.

Proof Let be finite-dimensional division algebra over .
Let , then consider the -subalgebra generated by . Every element in is a polynomial in , so is a quotient of the polynomial ring via the map . But then is a non-zero prime ideal, as the image is finite-dimensional over and doesn’t contain zero divisors. This implies for some , so .

We note the following corollary to 3.28 and 3.29

Corollary 3.30 Let be a semisimple algebra over a field and let be a list of all simple modules, up to isomorphism. Then and we have equality if is algebraically closed.

If we put in some knowledge about finite-dimensional divison algebras over (namely, the fact that the only ones are , so the dimension is at most 4), we also get the following:

Corollary 3.31 Let be a semisimple algebra over and let be a list of all simple modules, up to isomorphism. Then

These corollaries translate into statements about representations when we apply them to the group algebra .

Let’s close this post by recapitulating what we have shown about representations in the case where is finite and the characteristic of doesn’t divide the order of :

There are finitely many irreducible representations up to isomorphism(which are all finite-dimensional)

Every irreducible representation occurs as a direct summand of the so called “regular representation”, which is the representation corresponding to as a module over itself.

Every representation is a direct sum of copies of irreducible subrepresentations, even infinite-dimensional ones.

We know that for finite-dimensional representations the decomposition into a direct sum of irreducibles is unique up to isomorphism of the factors, including multiplicities. (I didn’t want to deal with cardinals for the infinite-dimensional case)

We have a nice formula that relates the dimension of irreducibles, the dimension of their endomorphism rings and the order of (which is obviously the dimension of ). If we don’t want to talk about the endomorphism rings, we still have an inequality, which is an equality in the algebraically closed case.

In the next post, we will continue our study of semisimple rings and give applications, e.g. by describing the number of irreducible representations in terms of the group .

In this post, we introduce the group algebra as another way to view representations and illustrate the usefulness of this approach by studying representations of cyclic groups by elementary ring theory. This is the second part of a series that started with this post. The numbering is consecutive, i.e. when I refer to some result 1.x, then this is written in that post.

A Review of Modules in Linear Algebra

We will begin by reviewing what modules over the polynomial ring mean in terms of linear algebra, as this will be helpful for motivating the module-theoretic perspective on representations.

Let be a field and be a (say finite-dimensional) vector space over and let be a -linear endomorphism of (so after choosing a basis, we can think of as a square matrix.) Suppose we wish to understand , e.g. find a basis such that has a particularly nice matrix representation with respect to that basis.

From the pair , we can define a -module structure on by defining -scalar multiplication via , where means that we apply to times.

Conversely, given a -module , we can think of it as a -vector space by restricting the scalar multiplication to . We also get a -linear endomorphism of given by multiplication with .

These constructions are inverse to each other: Going from a pair to the associated -module, multiplication with is precisely the endomorphism we started with.
For a -module, because every polynomial is a linear combination of powers of , we only need to know -scalar multiplication and how acts to reconstruct the -scalar multiplication.

Thus, we can think of pairs of vector spaces equipped with an endomorphism as -modules and we can translate between notions for endomorphisms and notions for .

Here’s an excerpt of a possible dictionary one might use for translation:

Pairs of vector spaces and endomorphisms

-modules

Subspaces that are invariant under , i.e.

-submodules

For pairs , , a -linear map such that

-linear maps

For pairs , , a -linear isomorphism such that

-linear isomorphisms

Eigenspace of associated to

The submodule of consisting of all elements annihilated by

The minimal polynomial of

The unique monic generator of the annihilator ideal associated to , i.e. the unique monic polynomial of minimal possible degree such that for all

One could add many more rows.

The important part for finding e.g. a nice basis for is the third row: If we can find a module that is isomorphic to the -module associated to such that we write down a basis such that we get a nice matrix representation for multiplication with , then the third row tells us that this is also a possible matrix representation for !

Now as is a PID, finitely generated modules over (in particular those modules that are finite-dimensional over ) are very well-understood. There’s a structure theorem that tells us that they are finite direct sums of modules of the form , where . (One can also put some conditions of to make them unique.) From there, one can easily deduce existence and uniqueness of canonical forms such as the Jordan normal form, the Frobenius normal form, and also properties of the minimal polynomial such as Cayley-Hamilton.

The Group Algebra

Let be a group and be a representation of over a field . By abuse of notation, we denote the action of an element on a vector by . Let , and , then there seems to be only one sensible way to define what we mean by , clearly, this has to be if any sensible rules hold.
But what is the expression supposed to mean? After all, we can’t just add an element of a group and an element of a field.

Or can we?

Definition 2.1 Let be a group (we denote the neutral element by ) and be a field, then the group algebra is defined as the vector space over freely generated by the elements of . We denote the elements of the basis corresponding to elements in by the same symbols. Group multiplication defines a multiplication of basis elements that we extend linearly in each argument. This defines a multiplication that extends the multiplication of and makes into a -algebra.

We leave the verification of the ring axioms to the reader. Intuitively, the group algebra consists of finite formal linear combinations of elements in , i.e. we can write them as where all but finitely many coefficients vanish. To compute a product of two such expressions, we expand using distributivity and then use the group multiplication to multiply the products of the basis vectors.

Lemma 2.2 For every representation of over , there is a unique way to define a -module structure that extends the given group action and -scalar multiplication, conversely, every -module gives rise to a representation in a canonical way. Using this identification, a morphism of representations corresponds precisely to a -linear map.

Proof Given a representation , and an element (this means the sum is finite), the only possible way to define such that the module axioms hold and acts via the given scalar multiplication and acts via the group action is to set .
Note that the RHS is just defined in terms of the group action and the vector space structure. One checks that this defines a module structure, using the linearity of the group action.
Conversely, if we have a -module , we can turn into a -vector space by restricting scalars to the subring .
We can also restrict the scalar multiplication to the subset . Associativitiy and unitality in the axioms for a module imply that this defines a group action.
Finally, group action and vector space operations are compatible due the equality in and associativity and distributivity of the scalar multiplication.
The correspondence of morphisms of representations and -linear maps follows by similar arguments: the idea is that every element in is a -linear combination of elements in , so it’s enough that a map commutes with -scalar multiplication and the -action to see that it preverses -scalar multiplication.

The relation between the description of linear-algebraic objects as -modules and representations as -modules is as follows:
In the former, we looked at any endomorphism without any condition, but only at one endomorphism at a time, that’s why the -algebra of choice to describe such an object is the polynomial algebra which is generated freely by one element , i.e. we don’t impose any relation.
For group representations, we consider many endomorphisms (actually automorphisms) at once, subject to all the relations that hold in the group . That’s why isn’t necessarily generated by one element and by inheriting the multiplication from , also inherits all the relations between elements in .

With lemma 2.2, we have added another characterization of representations to our collection (cf. lemma 1.3).
If one is really careful with the constructions in the lemma, one sees that it defines an isomorphism of categories which is just a formalization of the inuition that representations and -modules are exactly the same, just with a different point of view.

Let’s also mention the universal property of the group algebra, which can be quite useful even if you’re not a category-aficionado and implies lemma 2.2 as a special case.

Lemma 2.3 Let be a field and be a group, then for any -algebra and every group homomorphism to the group of units, there is a unique -algebra homomorphism that extends .

Proof The same argument as in lemma 2.2 applies: The only way we can define an extension that is -linear is by sending to , this just follows from the fact that is a basis for . One checks that because is a group homomorphism and the multiplication in is inherited from , this also respects the unit element and multiplication, so it is a -algebra homomorphism.

To see how this implies one direction in lemma 2.2, note that for a vector space , the endomorphism ring is a -algebra (here multiplication is composition) and for the group of units, we get .
Thus if we have a group homomorphism , the universal property tells us that there is a unique -algebra homomorphism . Now we can define a module structure by uncurrying:
Define for and
The fact that is a ring homomorphism translate neatly into the module axioms and -linearity gives us that the -scalar multiplication on remains the same.

Having this perspective is quite useful, because there are a lot of constructions for modules that now carry over directly to representations: we can form direct sums and products of representations, quotients etc. and all the properties of those constructions that we know to hold for modules also hold in this case. For example, subrepresentations as defined in 1.18 are the same as -submodules.

Representations of Cyclic Groups

We will use the accessible example of cyclic groups to show how the structure of the group algebra contains information about representations.

Lemma 2.4 If is cyclic of order , then , where the isomorphism sends to .

Proof One can take the map that sends \to and compute the kernel. As generates , so every element in is a polynomial in , which implies the surjectivity of that map.
Let’s instead show that both satisfy the same universal property:

If is any -algebra, then a -algebra homomorphism corresponds to a group homomorphism by lemma 2.3.
Since is generated by , a group homomorphism is uniquely determined by where it sends . As has order , we can send it precisely to those elements such that (This condition automatically give us that ). Thus has the following universal property for this choice of :
For any -algebra and every element such that , there’s a unique -algebra homomorphism that sends to .

If is still any -algebra, then by the homomorphism theorem, a -algebra homomorphism is the same as a -algebra homomorphism that sends to . A -algebra homomorphism is uniquely determined by where it sends and we can send it to every element in , but due to the condition that must be sent to , for homomorphisms from , we can send to precisely those elements such that .
Thus we have proved:
For any -algebra and every element such that , there’s a unique -algebra homomorphism that sends to .

At this point, to finish the proof, one can either mumble something about the Yoneda lemma with a smug expression or one can make the usual argument why two objects with the same universal property are isomorphic. (This should be familiar to anyone who has seen e.g. why the tensor product is unique)
Let’s do the latter: Because of the universal property of , we can find a unique -algebra homomorphism that sends to . This also works in the other direction: we get a unique -algebra homomorphism . Then is a -algebra homomorphism that sends to itself.
By the universal property, there can only be one such homomorphism, but we know that the identity is an example. Therefore .
By the same argument, .

Exercise Do a similar argument to determine the group algebra where is a product of two cyclic groups as a quotient of the polynomial ring in two variables. Why can this approach not work in this form for nonabelian groups?

We can use this to describe the representations of cyclic groups by decomposing with the Chinese remainder theorem. If we do that, we will end up with a product of rings, which is one of the reasons why it’s useful to think about modules over products of rings. If and are rings, then for every pair where is a -module and is a -module, we can make into an -module by having act on the left factor and on the right factors. The following lemma tells us that every -module arises in such a way:

Lemma 2.5 If and are rings, then every -module is isomorphic to a direct sum where is a -module and is a -module such that just acts on the first factor and just on the second one. and are canonically determined.

Proof Let be a -module. Consider the central idempotents . Then and . Then set and , we get that , so . It’s clear that acts trivialy on and acts trivially on which shows the statement. We can use the same and for all modues, which makes this decomposition canonical.

(Note: The above construction can be enhanced into a category equivalence of and )

Now let’s finally describe the representations of cyclic groups over !

If is cyclic of order , generated by , then by Lemma 2.4, , where the isomorphism sends to . Let , then we have the factorization , so by the Chinese remainder theorem, we get
Note that this is an isomorphism both of rings, but also of -modules, which means that we send to in each component.

Therefore, by lemma 2.5, every -module is a direct sum of -modules where varies. But for each , we have via sending to . Modules over a field are easy to understand: they are just a (possibly infinite) sum of . Thus we get that every -module is a direct sum of copies of .

Through all the isomorphisms, we have kept track where the generator is sent: we send it first to , then to (modulo something different in the CRT isomorphism), then to . This means that acts on the (one-dimensional) -module corresponding to by multiplication with . And in general, all modules are a direct sum of such modules (for different ), this means that really acts as a diagonal matrix where all the diagonal entries are -th roots of unity. (Even for infinite-dimensional representations.)

We can also say something about a more general setting. Suppose that the characteristic of does not divide . Then has distinct roots, so we can factorize where all are irreducible and pairwise distinct. Doing the same Chinese remainder theorem argument we get that:

. Now as the are irreducible, will be a field and the dimension over will be equal to the degree of , so we can again appeal to linear algebra and get the following result:

Lemma 2.6 Let be a cyclic group of order and let be a field such that the characteristic of does not divide and let be the factorization of into irreducibles. Then for every , There is a -module corresponding to such that the dimension of the module is equal to the degree of and in general, every -module is a direct sum of such modules.

Example 2.7 For , the only factors that can occur for are and quadratic factors of the form . By choosing a clever basis for the modules corresponding to the quadratic factors, one obtains rotation representations as in example 1.6 (though the angle of rotation will be instead of in the example.)

Example 2.8 For , the factorization of is well-known, it factors as , where is the -th cyclotomic polynomial. Thus the number of irreducible representations of over is equal to the number of divisors of and for each divisor , there’s an irreducible representation of degree .

We can also use this approach to say something about representations of cyclic groups in the case where the characteristic divides the group order. For simplicity, we just treat the case that has characteristic and is cyclic of order . The factorization of is just and we get. Here the Chinese remainder theorem doesn’t help.
But one can apply the structure theorem for finitely generated modules over a PID mentioned in the first section, noting that every -module is also a -module to get that every finitely generated -module is a direct sum of copies of and . If we look at the action of (which corresponds to the generator of ) on these modules, we see that it acts by multiplication with on , i.e. via the identity (we say “trivially”).
The action on is more interesting: Using the basis given by (the residue classes of) and , we see that the action of corresponds to a transvection action where is a generator of (cf. example 1.7)

We have seen how the algebraic structure of the group algebra can help to understand representations and in our example of cyclic groups, it turned out that when the conditions for Maschke’s theorem are satisfied, the group algebra is a product of fields.
We will investigate the structure of the group algebra in more detail in future posts and see that this was not a coindidence.

This blog post provides mostly some motivation, basic definitions and examples for group representations, up to Maschke’s theorem. Only familiarity with linear algebra and elementary group theory is required for understanding the main part of this post. However, there are some examples for readers with more background which can be safely ignored. The same is true for all categorical remarks.

This will be the first part of a series.

Introduction

The reason to care about groups is because they act on objects. Group actions arise in many different contexts and can provide insight (into the objects as well as into the groups which act on them).

The basic definition of a group action is an action on a set. A set can be thought of as an object without any structure except size (i.e. cardinality). For finite sets, this is more structure than it might seem: we can use counting and divisibility arguments which leads to results such as strong results on p-groups such as the Sylow theorems, the easy-to-prove but ubiquitous orbit-stabilizer theorem or Burnside’s lemma, which has nontrivial combinatorial implications.

Group actions are everywhere in pure mathematics and frequently the object which is acted upon has more structure than just being a set, e.g. a topological space. In these situations, the natural thing to investigate (or to require, if you’re writing a definition) is some compatibility between the group action and the structure on the object. In the example of a topological space, one would require the action to be continuous.

A common structure are vector spaces. Their usefulness seems to stem from the fact that they are both very well understood and still give one a lot of tools to work with: we have duals, tensor products, traces, determinants, eigenvalues etc. Thus, a technique that is used sometimes is “linearization” in which one tries to reduce a problem to linear algebra or at least gain insight by using linear-algebraic methods. Examples are the tangent space of a smooth manifold or variety (and for smooth maps the derivative) or the linearization of a nonlinear ODE.

Representations of groups can be thought of as a linearization of group theory, or more precisely as a linearization of group actions: One can be define them as actions of groups on vector spaces that respect the linear structure. They arise with an ubiquity comparable to (nonlinear, merely “set-theoretic”) group actions. When they do, they are arguably even more useful, since vector spaces have a lot more structure than sets, as described in the previous paragraph.

Group Representations

Definition 1.1 Let be a field. Then for a group , a (-linear) representation on a -vector space is a map that satisfies:

where is the neutral element.

Definition 1.2 In the above situation, the degree or dimension of the representation is the dimension of over .

Note that the first two axioms state that a representation is a group action and the other two axioms state that for any fixed the map is -linear. This map is also invertible, since the axioms imply that is an inverse. By the second axiom, we also get that the map is a group homomorphism. So by using a currying argument, we have seen that every group representation gives rise to a group homomorphism .

Conversely, given a group homomorphism , we can uncurry to get a representation on by setting

Thus we have another characterization, which allows us to apply concepts defined for group homomorphisms like kernel/image etc, whereas the first characterization allows us to apply notions defined for group actions.

While we’re at it, we may as well add a rephrasing in categorical language of the last characterization and get the following

Lemma 1.3 Let be a field, then for a group and a vector space over , the following data are equivalent:

A representation of on as in definition 1.1

A group homomorphism

A covariant functor from considered as a one-object category to the category of -vector spaces that sends the single object in to

This is the direct analog of equivalent characterizations of group actions: we can also view them as homomorphisms to the group of permutations of a set or as functors from a group to the category of sets.

(Viewing a group as a category works like this: Let be a group, then define a category with a single object and set . Composition , i.e. is just group multiplication. Associativity and having an identity follows from the group axioms.)

The last characterization allows one to apply constructions from category theory, such as composing representations with other functors, but we will not use it in this post except as an alternative descrition.

Remark 1.4 One can also consider representations of monoids or the case where is any ring and is a module.

Remark 1.5 We have defined only left representations. Reversing the chirality in the definitions is straightforward and gives rise to the notion of right representations.

Now for some examples.

As a zeroth example, note that representations of the trivial group are just vector spaces.

Example 1.6 Let be a finite cyclic group of order with a fixed generator , then a homomorphism from to any group is determined by where it sends and we can send to precisely those elements such that , so a representation of is just a linear automorphism that satisfies this equation.
For , one can take for example a rotation matrix to define a two-dimensional representation of .
For one can take to get a one-dimensional representation of . Both representations correspond to having act by a counterclockwise rotation of degrees. The former can be obtained from the latter by restricting scalars from to .

Example 1.7 Let , the additive group of , then acts on via transvections:

Example 1.8 If is a -set (a set equipped with an action from ), then we can consider a vector space such that the basis elements are indexed by . We can then define the action on the basis elements by setting . This permutation of the basis elements extends uniquely to a linear automorphism of and we get a respresentation, called the permutation representation associated to the group action.
From a categorical standpoint, if we view -sets as functors and representations as functors , then this construction is just composing a group action with the free module functor . (Thus this construction is also functorial with the notion of morphisms of representations to be defined later.)

Example 1.9 Let be any vector space. Let . Then the identity defines a representation. This corresponds to the natural action of on that comes from the definition of as -linear automorphisms.

Example 1.10 Generalizing the last example, all classical matrix groups such as , , , etc. are defined as subgroups of some general linear group, so that the subgroup inclusion defines a representation.

Example 1.11 Let be a finite group and let be a prime number. Suppose is a normal abelian subgroup of exponent . Then is a vector space and the conjugation action of on is -linear (this is automatic: any group homomorphism between vector spaces over is -linear.), thus we obtain a -linear representation.

Example 1.12 Let be a Galois extension. Then acts by definition on by -linear field automorphisms. We can just forget the “field automorphism” part and consider just as a -vector space, then we get a representation .
If and are number fields with rings of integers and and is a non-zero prime ideal in , then then acts on , giving a -linear representation.

Example 1.13 Let and let be any vector space over , then acts on where we tensor copies of . Then acts on by permuting the components of the tensors. Explicitly, if is an elementary tensor, then we can define the result of the action of on that to be .

Example 1.14 Let be a finite-dimensional -algebra, then the group of units acts on by conjugation and this action is -linear, and thus we obtain a representation of the unit group on the underlying vector space of the algebra. (If and , then a suitable restriction of the domain and codomain of this representation gives a description of the Hopf fibration.)

Example 1.15 In the same spirit as the last example, let be an algebraic group over . Let be the Lie algebra of . For any , the conjugation map is a smooth automorphism of , so we can take the derivative at the identity and get a linear automorphism . The map is a representation, called the adjoint representation of . (The same construction works verbatim for Lie groups.)

Example 1.16 Let be a smooth connected manifold and let be a vector bundle with a flat connection. Let be a base point and set and . If we take a smooth loop based at , parallel transport along that loop defines an automorphism of .
The flatness condition implies that this automorphism depends only on the homotopy class of and by smooth approximation, every homotopy class of continuous loops may be represented by a smooth loop, thus we obtain the holonomy representation . It turns out that this representation uniquely determines the flat bundle.

As is common practice with group actions, if is a representation, we also write just for or for the map . By further abuse of notation, we will also just call a representation of where the action is clear from the context.

Definition 1.17 If and are -linear representations of a group for some field , then a morphism of representations (also called intertwining operator) from to is a -linear map such that . (i.e. is -equivariant.)

Note that if we consider representations as functors, then a morphism of representations is just a natural transformation. Indeed, for any , naturality with respect to as a morphism is precisely the requirement that for all .

Example 1.17 In the situation of example 1.13, let , then we can define by acting on each factor: for an elementary tensor. Since we act in the same way in each component, this commutes with permutation of the factors, thus defines a morphism of the representation of given by permuting the factors in the tensor product.

Definition 1.18 If is a representation of , then a subspace that is -invariant (i.e. for all ) defines again a representation of . These subspaces are called subrepresentations of .

If is a subrepresentation of , then the inclusion is a morphism of representations, which gives a (quite general) family of examples for morphisms.

Example 1.19 In the situation of example 1.7, consider the subspace of spanned by , this is a subrepresentation because .

Example 1.20 Given a morphism of representations, the kernel and the image are subrepresentations of the domain and codomain, respectively.

Example 1.21 In the situation of example 1.8, suppose that is a sub -set, i.e. we have for all , then is itself a -set and if we apply the same construction to , the resulting vector space is a subspace of in a canonical way, and so also a subrepresentation. (This is a special case of the mentioned functoriality of this construction.)
If is finite, another subrepresentaion is given by the span of .

We now come to the first substantial theorem about representations.

Theorem 1.22 (Maschke) Let be a finite group and suppose that the order is invertible in . Then if is a finite-dimensional representation and is a subrepresentation, then there exists another subrepresentation such that ,.

Proof By linear algebra, we can find a -linear projection , i.e. we have that and is the identity on . We have that , but of course, will not be a morphism of representations in general. The idea is to “average” to get another projection onto that is a morphism of representations.
Set (Here we use that is invertible in ). This will be -linear again. This is a morphism of representations, as for , we have . Since is a subrepresentation and is the identity on , is also the identity on (it is crucial that we divided by for this step.) and the image is also contained in , so is still a projection onto .
Therefore, the kernel is a complement of and as is a morphism of representations, the kernel is a subrepresentation.

Example 1.23 To show that the assumptions in Maschke’s theorem are necessary, consider the transvection representation of the additive group of on described in example 1.7 and 1.19. Here acts via . As described in example 1.19, the subspace of vectors in with second component is a subrepresentation.
But this subrepresentation doesn’t have a complement that is also a subrepresentation: Indeed, if is any vector in such that , then and are linearly independent, as they are clearly not multiples of each other. Thus any subrepresentation that is not contained in is the whole of , so doesn’t have a complement.
This serves as a counterexample in two different ways: if we take to be a finite field, it shows that the assumption that the order is invertible is necessary. If we take to be an infinite field (say of characteristic ), then it shows that even in characteristic , the conclusion doesn’t need to hold when the group is infinite.

In this previous post, tensor products of -sets were introduced and some basic properties were proved, this post is a continuation, so I’ll asume that you’re familiar with the contents of that post.

In this post, unless specified otherwise, will denote groups. Groups will sometimes be freely identified with the corresponding one-object category. Left -sets will sometimes just be referred to as -sets.

After some lemmas, we will begin this post by some easy consequences of the Hom-Tensor adjunction, which is the main result of the previous post.

Lemma The category is complete and cocomplete and the limits and colimits look like in the category of sets (i.e. the forgetful functor is continuous and cocontinuous) with the “obvious” actions from . Similarly for .

Proof This is not too difficult to prove directly (you can reduce the existence of (co)limits to (co)products and (co)equalizers by general nonsense), but it also follows directly from the fact that is the functor category . The reason is that if and are categories and is (co)complete (and is small to avoid any set-theoretic trouble), then the functor category is also (co)complete and the (co)limits may be computed “pointwise”. In the case of , has only one object, so the (co)limits look like they do in .

Lemma If is a -set, is a -set and is a -set, then we have a natural isomorphism of -sets

Proof The proof is the same as the proof for modules, mutatis mutandis. Use the universal property of tensor products a lot to get well-defined maps and .

Lemma If is a subgroup, and we regard as a -set via left and right multiplication, then is naturally isomorphic to the restriction functor (this functor takes any -set, which we may think of as a group homomorphism or a functor and restricts it to the subgroup/subcategory given by .)

Proof Define a (natural) map via . This is -equivariant, because . On the other hand, given (which is just as a set), we can define via . This defines an inverse for .

Via the Hom-Tensor-Adjunction this implies

Corollary The restriction functor has a left adjoint .

The notation is chosen because we can think of this functor as an analog to the induced representation from linear representation theory, where we think of group actions as non-linear represenations. (Similar to the induced representation, one can give an explicit description of after choosing coset representatives for etc.)
In linear represenation theory, the adjunction between restriction and induction is called Frobenius reciprocity, so if we wish to give our results fancy names (as mathematicians like to do) we can call this corollary “non-linear Frobenius reciprocity”.

If we take to be the trivial subgroup, we obtain a corollary of the corollary:

Corollary The forgetful functor has a left adjoint, the “free -set functor”.

Proof If is the trivial group, then -sets are the same as sets and the restriction functor is the same as the forgetful functor. Since commutes with coproducts and is a one-point set, we can also describe this more explicitly: for a set , we have

We can also use the Hom-Tensor adjunction to get a description of some tensor products. Let denote a one-point set (simultanously the trivial group), considered as a -set with (necessarily) trivial actions.

Lemma For a -set , is naturally isomorphic to the set of orbits and both are left adjoint to the functor which endows every set with a trivial -action.

Proof Let be a set and be a -set. Denote the -set with as its set and a trivial action. If we have any , then must be constant on the orbits, since , so descends to a map of sets . Conversely, if we have any map , then we can define a -equivariant map by setting , where denotes the orbit of . These maps are mutually inverse natural bijection which shows that “set of orbits”-functor is left adjoint to . On the other hand, we can identify with (where the action is induced from the trivial right -action on ), so the left adjoint must be given by . Since adjoints are unique (by a Yoneda argument), we have a natural bijection

The set of orbits carries some information about the -set, but we can do a more careful construction which also includes in a natural way as part of the information.

Definition If is a -set, then the action groupoid is the category with and . Composition is given by .

The fact that this is called a groupoid is not important here, one can think of that as just a name (it means that every morphism in is an isomorphism).
The set of isomorphism classes of correspond to the orbits . For , the endomorphisms is the stabilizer group . The following lemma shows how to reconstruct a -set from , assuming that we know how all the Hom-sets lie inside .

Lemma (“reconstruction lemma”) If is a -set, then we define the functor with for all and for , we define the map via . Then we have

Proof For , define a map via . This defines a cocone over , so we get an induced map . can be described explicitly as , where the equivalence relation is generated by . To see that is surjective, note that is the image of . To see that is injective, suppose and are sent to the same element, i.e. , then we have , so that we may assume . Then implies that , so the two elements which map to the same element are already equal in .

The previous lemma can be thought of as a generalization of the orbit-stabilizer theorem. (The proof has strong similarities as well.) For illustration, let us derive the usual orbit-stabilizer theorem from it.

Lemma Let be a -set, then we have an isomorphism of -sets , where is the orbit of (with the restricted action) and is the coset space of the stabilizer subgroup with left multiplication as the action.

Proof We may replace with so that we have a transitive action. Then the previous lemma gives us an isomorphism .
Consider the one-object category . This can be identified with a full subcategory of corresponding to the object . Because we have a transitive action, all objects in are isomorphic (isomorphism classes correspond to orbits), so that the inclusion functor is also essentially surjective, so it is a category equivalence.
We may thus replace the colimit by the colimit . As has just one object, this colimit is a colimit over a bunch of parallel morphism , so it is the simultanous coequalizer of these morphisms. We know how to compute coequalizers in : the same way that we compute coequalizers in . So we have the families of maps , where varies over . The coequalizer is the quotient , where is generated by for each and . But this is exactly the equivalence relation that defines .

There is another case where the colimit takes a simple form after replacing with an equivalent category.

Lemma A -set is free in the sense that it is in the essential image of the “free -set functor” or equivalently it is a coproduct of copies of with the standard action iff the action of on is free in the sense that .

Proof It’s clear that if we have a disjoint union , then no element of other than can fix an element in . For the other direction, suppose that we have the condition . This implies that the morphism sets in the action groupoid are really small: Suppose such that , which implies that , so by assumption, thus . This means that for any pair of objects in , there is at most one morphism between them. So if we consider the set as a discrete category (i.e. the only morphisms are the identities), then if we take a representative for each orbit , this defines an inclusion of categories . As elements in represent isomorphism classes in , this inclusion is always essentially surjective. By our computations of the Hom-sets, it is also fully faithful if the action of on is free. So if we apply the “reconstruction lemma” we get . But a colimit over a discrete category is just a coproduct, so this is isomorphic to which shows that is free.

After some further lemmas, we will come to the main result of this post, which is also an application of the reconstruction lemma.

In the previous post, I described -sets in different ways, among them as functors , but I didn’t do the same for -sets. The following lemma remedies this deficiency.

Lemma-sets may be identified with left -sets or with functors or with functors . In other words, we have equivalences of categories .

The proof of this lemma is a lot of rewriting of definitions, not more difficult than proving the corresponding statements for one-sided -sets.

This lemma has a useful consequence, which one could also verify by hand:

Observation If is a functor and is a -set, then is a -set in a “natural” way.

Proof Think of as functor , composing with , gives us a functor , which we may also think of as a -set.
More explicitly, the action of on can be described as follows: for , the right-multiplication-map is left -equivariant, so it induces a left -equivariant map , we can define the action of on via this map.

The following lemma is an analog of the classical Eilenberg-Watts theorem from homological algebra which describes colimit-preserving functors as tensor products with a -bimodule.

Thereom (Eilenberg-Watts theorem for group actions)Every colimit-preserving functor is naturally equivalent to for a -set . One can explicitly choose (with the -set structure from the previous observation, as is a -set.)

Proof Let be a -set and be a -set, then we have a natural bijection
Using the reconstruction lemma, we get
For every , , so via the map . We need to consider how this identification behaves under the morphisms involved in the colimit. For , we have the map , this induces a map given by . If we make the indentification described above by evaluating both sides at , we get . Using the definition of the -action on the Hom-set , this left multiplication translates to right multiplication on . Because of the construction of the right -action on , this right multiplication is the map that is induced from right multiplication . We may summarize this computation by stating that
Using the assumption that preserves colimits, we get where we used the reconstruction lemma again in the last step.
We conclude by the Yoneda lemma.

This theorem (like the classical Eilenberg-Watts-theorem) is remarkable not only because it gives a concrete description of every colimit-preserving functor between certain categories, but also because it shows that such functors are completely determined by the image of one object and how it acts on the endomorphisms of that object (which are precisely the right-multiplications.)

It’s natural to ask at this point when two functors of the form and for -sets are naturally isomorphic. It’s not difficult to see that it is sufficient that and are isomorphic as -sets. The following lemma shows that this is also necessary, among other things.

Lemma For -sets and , every natural transformation is induced by a unique -equivariant map

Proof Assume we have a natural transformation , then we have in particular a left -equivariant map . We have and , so this gives us a -equivariant map which I call . Clearly is uniquely determined by this construction. For a fixed , right multiplication by defines a left -equivariant map . Under the isomorphism these maps describe the right action on . Naturality with respect to these maps implies that is right -equivariant.

This lemma allows a reformulation of the previous theorem.

Theorem (Eilenberg-Watts theorem for group actions, alternative version)
The following bicategories are equivalent:
– The bicategory where the objects are groups, 1-morphisms between two groups are -sets , where the composition of 1-morphisms is given by taking tensor products and 2-morphisms between two -sets are given by -equivariant maps.
– The 2-subcategory of the 2-category of categories where the objects are all the categories for groups , 1-morphisms are colimit-preserving functors and 2-morphisms are natural transformations between such functors.

This concludes my second blog post. If you want, please share or leave comments below.

Suppose is a ring, is a right -module and is a left -module, then we can form the tensor product that we all know and love. If we consider that a module is just an abelian group together with an action from a ring, one might ask the question: Can we imitate this construction for group actions?

It turns out that we can; this is what I’ll investigate in this post.

Recall that for a fixed group a left -set is a set together with a map that satisfies . An equivalent formulation is that a left -set is a set together with a group homomorphism , where denotes the group of bijections . Yet another way to phrase this definition is that a left -set is a functor from (regarded as a one-object category) to the category of sets.

There’s an obvious choice of morphisms for left -sets and , namely maps that satisfy . Traditionally called -equivariant maps. If you take the definiton via functors, then these are exactly natural transformations. It follows that the left -sets form a category, which we will denote by .

In a similar way, one defines right -sets as sets together with a map that satisfies , these can also be thought of as contravariant functors from to or equivalently as left -sets, where denotes the opposite group of . The category of right -sets will be denoted by .

If we have two groups and , then a -set is a set that is simultaneously a left -set and a right -set, such that the actions are compatible in the sense that . We get the category of -sets where the morphisms are maps that are both and -equivariant. Note that if we take or to be the trivial group, then -sets are equivalent to left -sets or right -sets respectively, thus we may always assume to deal with -sets and will cover all three cases. Also note that if we take both and to be the trivial group, then -sets are just sets.

We are now ready to begin our renarration of the story of tensor products, where groups play the role of rings, sets play the role of abelian groups and left and right -sets play the role of modules.

Since -Sets are important in the theory of tensor products for modules, we will study these first.

In the following, and will denote groups.

Lemma If is a -set and is a -set, then is a -set with the actions defined by and . If is a -set and is a -set, then is a -set in the analogous way.

The proof is a routine verification.

As a special case, when is just a set and is a -set, then is a -set, with the action on the opposite side. If is a -set, then the two actions we get this way are compatible, so that is a -set.

We can copy the following definition almost verbatim from the case for modules.

Definition If is a -set, is a -set and is a -set, then a map is called -balanced and -equivariant if and . We denote the set of all such maps by . If and are the trivial group, we drop them from the notation and just write .

Lemma If is a -set, is a -set and is any set, then is a -set with the actions defined by and .

This is again a routine verification, similar to the previous lemma.

We now come to the usual “Currying” argument.

Lemma If is a -set and is a -set and is any set, then there is a natural isomorphism of -sets

Proof We define the “Currying map” via , where . Or more compactly
Let us check that for the map is -equivariant, for is defined as . Because is -balanced, this equals , so .
Now we check that is – and -equivariant. Let , then for all , we have , on the other hand we have , this shows that .
Let , then for all , we have , on the other hand , so .
So we have shown that is indeed a well-defined -equivariant map .
To see that is bijective, note that an inverse is given by the “Uncurry”-map , where .
We omit the verification that is natural in , and .

We also give the following variants of the Currying isomorphism:

Lemma If is a -set, is a -set and is a -set, then we have a natural bijections
and

Proof The proof is very similar to the last one, so we omit some steps.
For the first bijection, let us just show that the map , where is well-defined.
For a fixed , we have , so is -equivariant.
Let , then .
So we get , thus is -equivariant.
For the second bijection, we use the map , where . The verification that this is a well-defined bijection is very similar to the previous computations.

We now come to the main definition of this post.

Definition Let be a right -set, be a left -set, then a tensor product is a set together with a -balanced map that satisfies the following universal property: for any set and -balanced map , there is a unique map such that .

Lemma In the situation of the previous definition, the tensor product exists and if is a second tensor product, then there exists a unique bijection such that .

Proof We first prove uniqueness. Suppose and , then because of the universal property of , we get a unique map such that and due to universal property of we get a unique map such that , then satisfies , but by the universal property of , there is a unique map that satisfies . We have just computed that satisfies this, but does, too. Thus . The proof that follows analogously.

Now we show existence. Consider the equivalence relation on generated by . We set and let be the quotient map. By construction, is -balanced.
We denote the image by . We have the relation . (Note that unlike in the case of modules, is surjective. So every element is an “elementary tensor”.)
Suppose is a set and is -balanced, then the map is well-defined and it is the unique map that satisfies . (This follows just from the universal property of a quotient set.)
In the case of modules, when we have a -bimodule and a -bimodule , then is a -bimodule. We know show the analogous result for -sets.

Lemma If is a -set and is a -set, then is a -set.

Proof Let , then the map is -balanced, because is a -set, so this map descends to a well-defined map , which shows that the map is well-defined. It’s clear that this makes into a left -set. In the same manner, we get a right action of on given by . These actions are compatible, since .

One of the basic properties of the tensor product of modules is that it defines a functors between module categories, this works also for -sets.

Lemma/Definition The tensor product can be made into a bifunctor

Proof Suppose and are -sets, and is a -equivariant map, and are -sets and is a -equivariant map. Consider the map . This is -balanced, because .
So we get a well-defined map , which we will denote by . is -equivariant because ist left -equivariant and is right -equivariant and the -set structure on a tensor product is defined by acting with on the left factor and with on the right factor.
If is another -set and is another -set and are morphisms of the respective type, then if we consider the map both and are maps which satisfy , thus by the uniqueness part of the universal property, they must be equal. That is clear from the definition.

Much of the utility of tensor products of modules lies in the Hom-Tensor-adjunction, which also has an analog for group actions. There’s not much left to do to prove it.

Theorem For a -set , the functor , is left-adjoint to the -functor .

Proof The universal property of the tensor product can be reformulated in the form that the map is a bijection. It’s not difficult to check that this map is natural in and and that if is a -set, then it restricts to a bijection . If we compose this bijection with the Currying bijection , we get a natural bijection

This concludes this first post on tensor products of -sets, I will investigate more properties of this construction in future posts. Feel free to leave comments below.